Oil Companies together with the Bush and Trump administration have kept the global warming debate alive long after most scientists believed that global warming was real and had potentially catastrophic consequences. We need to be aware and to change this policy before we get to the point of no return............Amor Patriae

ECOLOGY AND ENERGY PRODUCTION

Thursday, December 4, 2014

Is the 'big one' coming? Study warns huge 1,000km long fault where megaquake will originate is 'eerily quiet'

Is the 'big one' coming? Study warns huge 1,000km long fault where megaquake will originate is 'eerily quiet'

Cascadia 'megathrust' fault is a 1,000 Km long dipping fault

It stretches from Northern Vancouver Island to Cape Mendocino California

Researchers believe fault is 'locked' and pressure building in it

The fault zone expected to generate the next 'big one' earthquake has gone silent.

Researchers are baffled by the lack of activity at the 1,00km long Cascadia fault which stretches from Northern Vancouver Island to Cape Mendocino in California.

Experts believe the lack of activity could point to a build up of pressure - which could lead to a massive killer quake.

The Cascadia Subduction Zone (CSZ) 'megathrust' fault is a 1,000 Km long dipping fault that stretches from Northern Vancouver Island to Cape Mendocino California.It separates the Juan de Fuca and North America plates.

New Juan de Fuca plate is created offshore along the Juan de Fuca ridge.

The Juan de Fuca plate moves toward, and eventually is shoved beneath, the continent (North American plate).

Two independent research initiatives have both found the same thing - the sound of silence under the sea.

The Cascadia earthquake fault zone lies underwater between 40 and 80 miles offshore of the Pacific Northwest coastline.

Earthquake scientists have listening posts along the coast from Vancouver Island to Northern California, and have been using ships to drop off and later retrieve ocean bottom seismographs.

These record for up to a year right on top of the fault zone.

However, they have detected few signs of the grinding and slipping they expected.

It is 'a puzzle,' according to University of Oregon geophysics professor Doug Toomey.

'What is extraordinary is that all of Cascadia is quiet. It's extraordinarily quiet when you compare it to other subduction zones globally,' Toomey told the Seattle pi.

Two teams have been examining the area.

A joint Japanese-Canadian team dropped instruments offshore of Vancouver Island, while Toomey's team is in its fourth year of deployments.

Named the Cascadia Initiative, it is rotating among subduction zone segments offshore of Washington, Oregon and Northern California.

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Researchers have been using ships to drop off and later retrieve ocean bottom seismographs - but still say the fault remains 'eerily quiet'.

The Cascadia Initiative (CI) is an onshore/offshore seismic and geodetic experiment that takes advantage of an Amphibious Array to study questions ranging from megathrust earthquakes to volcanic arc structure to the formation, deformation and hydration of the Juan De Fuca and Gorda plates.

Researchers say the area is 'locked'.

The Japanese-Canadian team, which published their research in the Bulletin of the Seismological Society of America, wrote: 'The lack of interplate seismicity is interpreted to reflect complete healing and locking of the megathrust over three centuries after the previous great earthquake,' wrote Koichiro Obana and his co-authors in the BSSA paper.

Experts say this could cause major problem.

'If there were low levels of offshore seismicity, then we could say some strain is being released by the smaller events,' Toomey said.

'If it is completely locked, it means it is increasingly storing energy and that has to be released at some point.'

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The Cascadia Initiative (CI) is an onshore/offshore seismic and geodetic experiment that takes advantage of an Amphibious Array to study questions ranging from megathrust earthquakes to volcanic arc structure to the formation, deformation and hydration of the Juan De Fuca and Gorda plates.

Toomey described himself as 'very concerned' and said it is 'imperative' people in the Northwest continue to prepare for a big earthquake.

The last full rip of the Cascadia Subduction Zone happened in January 1700.

The exact date and destructive power was determined from buried forests along the Pacific Northwest coast and an 'orphan tsunami' that washed ashore in Japan.

Geologists digging in coastal marshes and offshore canyon bottoms have also found evidence of earlier great earthquakes and tsunamis.

The inferred timeline of those events gives a recurrence interval between Cascadia megaquakes of roughly every 400 to 600 years, reports the Pacific Northwest Seismic Network.

The great San Francisco earthquake and fire of April 18, 1906. "Pine Street below Kearney." Aftermath of the great San Francisco earthquake and fire of April 18, 1906.

IN THE ZONE: Diablo Canyon Nuclear Plant in California sits within the most active earthquake zone in the United States. (Photo: emdot/Flickr)

Nuclear power is under the microscope as much of the world watches the aftermath of the Japanese earthquake and the resulting tsunamis.

Let’s take a look at which nuclear power plants sit in the seismically active areas of the United States.

Generally, this concern is focused on the West Coast of the United States, because that's where most of our large earthquakes have occurred. There are no nuclear power plants in Hawaii or Alaska, but there are four nuclear reactor sites along the West Coast — one nuclear reactor site in Washington, two in California and one in Arizona.Here's a link to an interesting site, nukepills.com, where you can see the location of all nuclear power plants as well as the theoretical fallout zones.

Below, you can see the locations of the power plants, minus the fallout zones:

Now, these are just the power plants. There is a whole other issue with non-power nuclear reactors. These aren’t power plants, but research facilities such as universities where smaller-scale reactors are located. In all, there are eight of these sites along the West Coast. One is in Arizona, four are in California, two are in Oregon and one is in Washington. In all, the United States has 36 of these smaller sites, which can be seen below:

As you can see, most of the nuclear power plants and research facilities lie in the middle of the country. A good number that lie the West Coast are in the most seismically active parts of the nation, as this map from the United States Geological Survey shows:

Over the course of history, the concerns surrounding the nuclear industry have been focused on accidents that occurred despite safety regulations. This is what caused Chernobyl, and what has been blamed for the cause of Three Mile Island. While earthquakes and tsunamis can't be controlled, we can control what we know. And these maps allow us to know where the risks lie when it comes to nuclear industry and earthquakes.

On March 27, 1964, a megathrust earthquake struck Alaska, about 15 miles below Prince William Sound, halfway between Anchorage and Valdez. The quake had a moment magnitude of 9.2, making it the second most powerful earthquake ever recorded. The initial quake and subsequent underwater landslides caused numerous tsunamis, which inflicted heavy damage on the coastal towns of Valdez, Whittier, Seward, and Kodiak. Alaska's biggest city, Anchorage, suffered numerous landslides, destroying city blocks and neighborhoods. An estimated 139 people were killed, most by tsunamis -- including 16 deaths on Oregon and California shorelines. The old town site of Valdez was abandoned, with reconstruction taking place on stable ground nearby. This is the fourth of five entries focusing on events of the year 1964 this week (and next Monday). Monday's entry will feature images of the New York World's Fair.

The rails in this approach to a railroad bridge near the head of Turnagain Arm, southeast of Anchorage, were torn from their ties and buckled laterally by movement of the riverbanks during a massive earthquake on March 27, 1964. The bridge was also compressed and developed a hump from vertical buckling. (U.S. Geological Survey)

Downtown Anchorage, the collapse of Fourth Avenue near C Street, due to a landslide caused by the earthquake. Before the shock, the sidewalk on the left was at street level with the one on the right. (U.S. Army) #

The dock area, a tank farm, and railroad facilities in Whittier, Alaska were severely damaged by surge-waves developed by underwater landslides in Passage Canal, on March 27, 1964. The waves inundated the area of darkened ground, where the snow was soiled or removed by the waves. (U.S. Geological Survey) #

The waterfront of Seward, Alaska, weeks after the earthquake, looking north. Note the "scalloped" shoreline left by the underwater landslides, the severed tracks in the railroad yard which dangle over the landslide scarp, and the wind row-like heaps of railroad cars and other debris thrown up by the tsunami waves. (U.S. Geological Survey) #

The Four Seasons Apartments in Anchorage was a six-story lift-slab reinforced concrete building which collapsed during the earthquake. The building was under construction, but structurally completed, at the time of the quake. (U.S. Geological Survey) #

An unidentified man sits at a desk beside hi-fi sets moved to the middle of Fourth Avenue in Anchorage on March 31, 1964. The items were moved from a store that was demolished in the earthquake. (AP Photo) #

The path of destruction made by the quake in Alaska followed by a tsunami can be seen in this aerial view of Kodiak on March 29, 1964. The wave swept in from the lower left and towards upper right, pushing and smashing everything in its way. (AP Photo) #

Chaotic condition of the commercial section of Kodiak following inundation by seismic sea waves. The small boat harbor contained an estimated 160 crab and salmon fishing boats when the waves struck. (U.S. Navy/NOAA) #

A view of the destruction of Valdez, Alaska. Thirty-one residents died during the earthquake and subsequent tsunami. Instability and vulnerability to future tsunamis made the old town site too dangerous to rebuild, so the town was relocated several miles west to more stable ground, and rebuilt. (NOAA) #

Tsunami damage and high-water line at Seward. The tsunami waves washed the snow from the lower slopes of the hillsides, and the height of the highest wave is marked by the sharp "snow line" on the hillside behind and just above the rooftop at left center.(U.S. Geological Survey) #

Support columns punched through the deck of the Twentymile River Bridge, as it collapsed during the earthquake, near Turnagain Arm on Cook Inlet. The adjacent steel railroad bridge survived with only minor damage. (U.S. Geological Survey) #

This highway embankment fissured and spread, cracking down the middle. The road was built on thick deposits of alluvium and tidal estuary mud along Turnagain Arm near Portage. (U.S. Geological Survey) #

With the city under martial law, soldiers patrol a downtown street in Anchorage, Alaska, on March 28, 1964. In background is the wreckage of the five-story J.C. Penney's store at Fifth Avenue and D Street. (AP Photo) #

The head of the L Street landslide in Anchorage. The land on the left side sank 7 to 10 feet in response to 11 feet of horizontal movement of the lower section of the slide. A number of houses were undercut or tilted by subsidence of the graben. Note also the collapsed Four Seasons Apartment Building and the undamaged three-story reinforced concrete frame building behind it, which are on more stable ground. (U.S. Geological Survey) #

Trees up to 24 inches in diameter and 100 feet above sea level were broken and splintered by the surge wave generated by an underwater landslide in Port Valdez on Prince William Sound. (U.S. Geological Survey) #

This truck was bent around a tree by the surge waves generated by the underwater landslides along the Seward waterfront. The truck was about 32 feet above water level at the time of the earthquake. (U.S. Geological Survey)

May 24, 2013 – KAMCHATKA – A magnitude 8.3 earthquake struck off Russia’s eastern coast on Friday, briefly prompting a tsunami scare but causing no casualties or substantial damage, Russian emergency authorities said. The epicenter of the quake was located at a depth of 385 miles in the Sea of Okhotsk, 244 miles west of the nearest city, Petropavlovsk-Kamchatsky, the U.S. Geological Survey said. The quake was felt in Petropavlovsk-Kamchatsky, the main city on the Kamchatka peninsula and home to a nuclear submarine base, and on Sakhalin Island, where Russia’s largest liquefied natural gas project is located. The earthquake struck 608 km (377 miles) below the ocean- diminishing any tsunami risks. Regional emergency authorities issued a tsunami warning for Sakhalin and the Kurile Islands, advising residents of dangerous areas to seek high ground, but lifted the warning several minutes later. Residents of northern Japan felt the quake but there was no tsunami warning from Japan’s meteorological agency. It’s the second major earthquake to strike the planet in 24 hours. A 7.4earthquake struck the region of Tonga, in the South Pacific, hours earlier. –Reuters

Pacific Plate turbulence increases: At 103 million square kilometers, the Pacific plate is the largest of the tectonic plates and consequently the most violent. Geological forces are tearing at the integrity and stability of this large lithospheric cross-section of the planet. As I reported several days ago, seismic tension was mounting along the Pacific tectonic plate. The cascading series of earthquakes over the last 24 hours are yet one more indication that dynamic geological change is accelerating within the interior of the planet. These processes of change will have profound implications for the entire Ring of Fire and all subduction zones located within this region.

May 24, 2013 – CALIFORNIA - An earthquake in far northeastern California was felt by thousands of people as far away as San Francisco and in two other states, but there have been no reports of injury or serious damage. The magnitude-5.7 quake broke dishes and shook mirrors when it struck at 8:47 p.m. Thursday, officials said. It was centered near Greenville, about 25 miles southwest of Susanville in far northeastern California, said Rafael Abreu, a geophysicist with the U.S. Geological Survey’s National Earthquake Center in Golden, Colo. There have been several aftershocks, including a magnitude 4.9 that struck early Friday morning. Slight damage has been reported including objects falling from shelves and dishes rattled or broken, according to a report from the National Weather Service. Susan Shephard and her husband Alan Shephard, who run the Quail Lodge at Lake Almanor near Greenville very close to the epicenter, said they were watching “The Hunger Games” on TV when the whole building started shaking. “All of a sudden things started falling off the shelves, mirrors fell off the wall, vases fell down to the floor, everything started crashing,” Shephard told the Redding Record-Searchlight. “It felt like the end of our world.” The Susanville Fire Department said it had received no reports of damage, and a Plumas County Sheriff’s Office dispatcher said calls were flooding into its office but no reports of damage. Thousands of people reported feeling the quake, as far away as the San Francisco Bay area and across the borders into Oregon and Nevada, according to the USGS website. KCRA-TV in Sacramento reported that the Plumas County temblor was felt in downtown Sacramento, about 145 miles south of the epicenter. People in Yuba and Sutter Counties, south of Plumas, said they felt a rolling quake, according to the Marysville Appeal-Democrat. “People in the area felt a strong jolt, but it was not enough to generate serious damage, based on early field reports,” Abreu said.

October 23, 2013 – SEATTLE – You already know Seattle is due for a devastating earthquake, but a new study shows one more thing to worry about: Landslides. Seattle is full of slope-side real estate with gorgeous views of Lake Washington and Puget Sound. It’s also primed for possible disaster, thanks to these very same hilly areas that could hurtle into the water during the next big earthquake. Published Tuesday in the Bulletin of the Seismological Society of America, the study found that damage from earthquake-triggered landslides will be worse and more widespread in Seattle than previously thought. The study focused on the Seattle Fault, a 30-mile fracture that runs east-west through Seattle, under CenturyLink Field and over to Issaquah. Capable of inflicting mass damage, it’s due for another rupture, but no one knows when. “A major quake along the Seattle Fault is among the worst case scenarios for the area since the fault runs just south of downtown,” said Kate Alltstadt, a University of Washington doctoral student and co-author of the study.

Then there’s Seattle’s rain and craggy topography, a recipe for landslides. Allstadt and the research team wondered: How would a magnitude 7.0 quake along the Seattle Fault affect the city’s crumbly slopes? Answer: Catastrophe. The study found that thousands of landslides would ravage Seattle’s coastal bluffs and southern neighborhoods. More than a 1,000 buildings would be in hazard zones of collapsing hills, the study found. But that when the soil was dry. A far worse threat loomed when hills were soggy. More than 8,000 buildings would be in potential danger if a major earthquake hit after a rainy spell. “A lot of people assume that all landslides occur in the same areas, but those triggered by rainfall or human behavior have a different triggering mechanism than landslides caused by earthquakes, so we need dedicated studies,” said Allstadt, who’s also a seismologist with the Pacific Northwest Seismic Network. The Seattle Fault last ruptured in 900 A.D., at an estimated magnitude 7.4. It wreaked geologic havoc, sending chunks of forest into Lake Washington. Seattle was not yet a city then, and the next rupture has the deadly potential to bring down thousands of homes. When will this happen? One estimate puts the quake recurrence at every 750 years. Another says every 200 to 12,000 years. One thing is known: Seattle is due; the fault last ruptured more than 1,100 years ago. –Seattle PI

Two Contrasting Models of Lithospheric Structure

The subduction of the Juan de Fuca plate beneath North America changes markedly along the length of the subduction zone, notably in the angle of subduction, distribution of earthquakes, volcanism, geologic and seismic structure of the upper plate, and regional horizontal stress. To investigate these characteristics, we conducted detailed density modeling experiments of the crust and mantle along two transects across the Cascadia subduction zone. One crosses Vancouver Island and the Canadian margin, and the other crosses the margin of central Oregon. Both density models were constructed independently to a depth of approximately 50 km. We gathered all possible geologic, geophysical, and borehole data to constrain the density calculations. The final densities for the Oregon and Vancouver lithosphere models were obtained from gravity inversions.

Our results confirm that the downgoing slab of the Cascadia subduction zone dips significantly steeper beneath Oregon than beneath Vancouver Island, lending support to the idea that the Juan de Fuca plate is segmented from north to south. In addition, our gravity models indicate that the mantle wedge beneath western Oregon (i.e., below the western Cascades) is lighter than the mantle beneath the Canadian continental crust. This low density agrees with the low mantle velocities observed in the mantle and the present day extensional regime of the Pacific Northwest.

A gravity low at the deformation front of the Oregon margin, absent along the Vancouver margin, can be explained by the different bathymetry of the two regions and by the depth to the top of the subducting Juan de Fuca plate. If the accretionary prisms along these profiles were modeled with equal densities, a density in homogeneity in the lower part of the models would be necessary. Thus that the density of the accretionary prism for the Vancouver profile must be approximately 0.1-0.2 g/cm3 greater than that for Oregon. A density difference within the accretionary prisms also agrees with other data. We note that the volume of accreted sediments is approximately twice as large along the Vancouver profile than along the Oregon profile, and the prism reaches a greater depth (approximately 20 km as compared with 12 km for the Oregon profile). This implies that the sediments within the accretionary prism at Vancouver Island are at a higher metamorphic grade, and therefore have higher densities.

We find that a substantial part of the coastal gravity maxima for both lines is caused by increasing density with depth in the subducting plate. In the proposed model, the maximum possible density of the slab was used to satisfy constraints for the average density of the near coastal crust for both profiles. If a density increase with depth is not introduced into the model, very high densities would be required for the near surface coastal and continental crustal blocks.

View the Vancouver or the Oregon profile at a larger scale annotated with density values.

Cascadia subduction zone

Structure of the Cascadia subduction zone

Area of the Cascadia subduction zone

In the past 25 years, scientists have developed a theory -- called plate tectonics -- that explains the locations of volcanoes and their relationship to other large-scale geologic features. ...

According to this theory, the Earth's surface is made up of a patchwork of about a dozen large plates that move relative to one another at speeds from less than one centimeter to about ten centimeters per year (about the speed at which fingernails grow). These rigid plates, whose average thickness is about 80 kilometers, are spreading apart, sliding past each other, or colliding with each other in slow motion on top of the Earth's hot, pliable interior. Volcanoes tend to form where plates collide or spread apart, but they can also grow in the middle of a plate, as for example the Hawaiian volcanoes.

The boundary between the Pacific and Juan de Fuca Plates is marked by a broad submarine mountain chain about 500 kilometers long, known as the Juan de Fuca Ridge. Young volcanoes, lava flows, and hot springs were discovered in a broad valley less than 8 kilometers wide along the crest of the ridge in the 1970's. The ocean floor is spreading apart and forming new ocean crust along this valley or "rift" as hot magma from the Earth's interior is injected into the ridge and erupted at its top.

In the Pacific Northwest, the Juan de Fuca Plate plunges beneath the North American Plate. As the denser plate of oceanic crust is forced deep into the Earth's interior beneath the continental plate, a process known as subduction, it encounters high temperatures and pressures that partially melt solid rock. Some of this newly formed magma rises toward the Earth's surface to erupt, forming a chain of volcanoes (the Cascade Range) above the subduction zone.

Ocean floor is sinking below the continental plate offshore of Washington and Oregon. The North American Plate moves in a general southwest direction, overriding the oceanic plate. The Cascadia Subduction Zone is where the two plates meet.

Tectonic processes active in the Cascadia subduction zone region include accretion, subduction, deep earthquakes, and active volcanism that has included such notable eruptions as Mount Mazama (Crater Lake) about 7,500 years ago, Mount Meager about 2,350 years ago and Mount St. Helens in 1980.

The width of the Cascadia subduction zone varies along its length, depending on the temperature of the subducted oceanic plate, which heats up as it is pushed deeper beneath the continent. As it becomes hotter and more molten, it eventually loses the ability to store mechanical stress and generates earthquakes. On the Hyndman and Wang diagram (not shown, click on reference link below) the "locked" zone is storing up energy for an earthquake, and the "transition" zone, although somewhat plastic, could probably rupture.

Earthquakes

Cascadia earthquake sources

Earthquake magnitude

The Cascadia subduction zone can produce very large earthquakes ("megathrust earthquakes"), magnitude 9.0 or greater, if rupture occurs over its whole area. When the "locked" zone stores up energy for an earthquake, the "transition" zone, although somewhat plastic, can rupture. Great Subduction Zone earthquakes are the largest earthquakes in the world, and can exceed magnitude 9.0. Earthquake size is proportional to fault area, and the Cascadia Subduction Zone is a very long sloping fault that stretches from mid-Vancouver Island to Northern California. It separates the Juan de Fuca and North American plates. Because of the very large fault area, the Cascadia Subduction Zone could produce a very large earthquake. Thermal and deformation studies indicate that the locked zone is fully locked for 60 kilometers (about 40 miles)downdip from the deformation front. Further downdip, there is a transition from fully locked to aseismic sliding.

In 1999, a group of Continuous Global Positioning System sites registered a brief reversal of motion of approximately 2 centimeters (0.8 inches) over a 50 kilometer by 300 kilometer (about 30 mile by 200 mile) area. The movement was the equivalent of a 6.7 magnitude earthquake. The motion did not trigger an earthquake and was only detectable as silent, non-earthquake seismic signatures.

Earthquake timing

The last known great earthquake in the northwest was the 1700 Cascadia earthquake. Geological evidence indicates that great earthquakes may have occurred at least seven times in the last 3,500 years, suggesting a return time of 300 to 600 years. There is also evidence of accompanying tsunamis with every earthquake, and one line of evidence for these earthquakes is tsunami damage, and through Japanese records of tsunamis.

The next rupture of the Cascadia Subduction Zone is anticipated to be capable of causing widespread destruction throughout the Pacific Northwest.

Other similar subduction zones in the world usually have such earthquakes every 100 to 200 years; the longer interval here may indicate unusually large stress buildup and subsequent unusually large earthquake slip.

San Andreas Fault connection

Studies of past earthquake traces on both the northern San Andreas Fault and the southern Cascadia subduction zone indicate a correlation in time which may be evidence that quakes on the Cascadia subduction zone may have triggered most of the major quakes on the northern San Andreas during at least the past 3,000 years or so. The evidence also shows the rupture direction going from north to south in each of these time-correlated events. The 1906 San Francisco earthquake seems to have been a major exception to this correlation, however, as it was not preceded by a major Cascadia quake.

Recent findings concluded the Cascadia subduction zone was more hazardous than previously suggested. The feared next major earthquake has some geologists predicting a 10% to 14% probability that the Cascadia Subduction Zone will produce an event of magnitude 9 or higher in the next 50 years; however, the most recent studies suggest that this risk could be as high as 37% for earthquakes of magnitude 8 or higher.

Three days after a massive earthquake that is now estimated to have registered a 9.0 magnitude, Japanese rescue crews are being joined by foreign aid teams in the search for survivors in the wreckage. Japan's Prime Minister Naoto Kan has called the disaster nation's worst crisis since World War II, as the incredible scope of the destruction becomes clear and fears mount of a possible nuclear meltdown at a failing power plant. It is still too early for exact numbers, but the estimated death toll may top 10,000 as thousands remain unaccounted for. Gathered here are new images of the destruction and of the search for survivors. [This is a follow-up to an earlier entry:

Diablo Canyon Power Plant, 2009 photo from offshore. The light beige domes are the containment structures for Unit 1 and 2 reactors. The brown building is the turbine building where electricity is generated and sent to the grid. In the foreground is the Administration Building (black and white stripes).

Unit Two

Unit Two is a 1,118 MWe pressurized water reactor supplied by Westinghouse. It went online on March 3, 1986 and is licensed to operate through August 20, 2025.[8] In 2006, Unit Two generated 8,520,000 MW·h of electricity, at a capacity factor of 88.2 percent.

The plant draws cooling water from the Pacific Ocean, and during heavy storms both units are throttled back by 80 percent to prevent kelp from entering the cooling water intake. The cooling water is used once and is not recirculated but rather returned to the Pacific Ocean at a minutely higher temperature.

Earthquake hazard

Diablo Canyon was originally designed to withstand a 6.75 magnitude earthquake from four faults, including the nearby San Andreas and Hosgri faults, but was later upgraded to withstand a 7.5 magnitude quake. It has redundant seismic monitoring and a safety system designed to shut it down promptly in the event of significant ground motion.

Pacific Gas & Electric Company went through six years of hearings, referenda and litigation to have the Diablo Canyon plant approved. A principal concern about the plant is whether it can be sufficiently earthquake-proof. The site was deemed safe when construction started in 1968.

By the time of the plant's completion in 1973, a seismic fault, the Hosgri fault, had been discovered several miles offshore. This fault had a 7.1 magnitude quake 10 miles offshore on November 4, 1927, and thus was capable of generating forces equivalent to approximately 1/16 of those felt in the 1906 San Francisco earthquake.[

The company updated its plans and added structural supports designed to reinforce stability in case of earthquake. In September 1981, PG&E discovered that a single set of blueprints was used for these structural supports; workers were supposed to have reversed the plans when switching to the second reactor, but did not.[12]According to Charles Perrow, the result of the error was that "many parts were needlessly reinforced, while others, which should have been strengthened, were left .untouched." Nonetheless, on March 19, 1982 the Nuclear Regulatory Commission decided not to review its 1978 decision approving the plant's safety, despite these and other design errors.

This disaster in Japan can happen here in California after a similar tsunami hits the West Coast

we learned that four of six Fukushima nuclear reactor sites are irradiating the earth, that the fire is burning out of control at Reactor No. 4's pool of spent nuclear fuel, that there are six spent fuel pools at risk all told, and that the sites are too hot to deal with. On March 16 Plumes of White Vapor began pouring from crippled Reactor No. 3 where the spent fuel pool may already be lost. Over the previous days we were told: nothing to worry about. Earthquakes and after shocks, tidal wave, explosions, chemical pollution, the pox of plutonium, contradicting information too obvious to ignore, racism, greed -- add these to the original Four Horsemen of the Apocalypse: Conquest, War, Famine and Death. The situation is apocalyptic and getting worse. This is one of the most serious challenges humanity has ever faced.

While the absence of cooling water facilitated the nuclear crises in Japan, most likely some major reactor components (proven unsafe) also failed under the seismic stresses of the 9.0 quake. Key components likely cracked or shattered. The tsunami and huge aftershocks advanced the chaos. These factors were complicated by the loss of offsite electrical power (an electrical BLACKOUT), the failure of emergency diesel generators, and the subsequent loss-of-coolant (water).Embrittlement of nickel-based superalloys that comprise reactor internals was flagged as a major safety issue as early as the 1960s, yet such problems were bureaucratically dismissed, covered over, buried in paperwork and regulatory studies produced by the NRC ("NUREG" documents), and ignored. Intergranular stress corrosion cracking of BWR core shrouds (the core shroud is next to fuel rods deep inside) is another major safety issue in GE designed BWRs built by Hitachi at Fukushima, and these plague every BWR reactor in the U.S.

The Tokyo Electric Power Company's (TEPCO) house of cards is toppling, as it has now been revealed that three reactors at the crippled Fukushima Daiichi nuclear power facility all melted shortly after the devastating earthquake and tsunami hit them on March 11 (http://www.bloomberg.com/news/2011-...). TEPCO also now admits that holes likely exist in the reactors' containment vessels as a result, which explains the persistent water leaks and drastic temperature fluctuations that led to continuous containment problems (http://www3.nhk.or.jp/daily/english...).TEPCO officials claim that the company has never hidden any of this information from the public, but that recent data analysis has confirmed what many scientists and experts had correctly predicted weeks ago based on observation of the situation. And rightfully so, many remain critical of TEPCO's drastic underestimation of the true condition of the plant, and say the company's unrealistic optimism since the disaster first occurred has been wholly misleading, and not at all based in reality.The entire faulty approach taken by TEPCO throughout this unfolding mega-disaster can be compared to the following scenario:A major vehicle accident has caused the engine of a semi-truck carrying a large fuel tank to catch fire and explode, which has obviously destroyed the truck's internal computer monitoring system and rendered it non-operational. The large fuel tank on the back of the truck has not yet caught fire, but instead of making a logical assessment based on simple observation that the situation is very serious, and that the fuel tank could soon catch fire, emergency responders (TEPCO) instead say that, because there is no way to run a computer analysis of the truck's engine, there is no way to know for sure to know exactly what is going on. So they instead pour water all over the engine and allege that everything is just fine, instead of making the logical decision to unhinge the truck from the fuel tank and fix the situation as quickly as possible. In the end, more explosions take place, and eventually the disaster escalates into a much worse one.The only difference between this truck scenario and Fukushima is the fact that large explosions already took place very early on, which should have been an obvious indicator that things were out of control at the plant. But TEPCO officials, with the apparent approval of the Japanese government, minimized the severity of the situation since nothing could be confirmed with concrete data, despite the fact that nuclear experts everywhere observed the "symptoms" of the disaster, and had come to logical conclusions early on that meltdowns were likely taking place.So instead of doing what most people would consider to be the right thing, and admitting that the plant was most likely beyond containment -- and that entombing it as quickly as possible in order to avoid the continuous spewing of radioactive particles into the environment was the best option to take -- TEPCO has instead been playing around with ocean water (http://www.naturalnews.com/031978_r...) and ridiculous polyester tents (http://www.naturalnews.com/032400_F...), all while radioactive materials continue to leak into the atmosphere, groundwater, and oceans. Clearly, things are amiss in the way the entire thing is being handled by those who are expected to be most privy to the nature of nuclear technology and how it behaves under current conditions.The most recent reports available explain that a shocking 94 percent of the fuel in Reactor 3 may have melted into containment water just three days after the May 11 disaster (http://www.world-nuclear-news.org/R...). Reactor 3, of course, contains the deadly, plutonium-based MOX fuel that is actually capable of "breeding" itself and regenerating beyond its original mass. And at this point in time, Reactors 1, 2, and 3 have all likely had their entire fuel rods completely melt, creating holes in the containment vessels that are leaking and spreading unknown levels of radiation directly into the environment. And to make matters even worse, a "very intense" super typhoon, Songda, is making its way across the Pacific Ocean where it is expected to hit Japan in the next couple of days. This Category 5 storm is seeing sustained winds of 161 miles per hour (mph) and gusts of up to 195 mph, according to CNN(http://news.blogs.cnn.com/2011/05/2...). Though the storm system is expected to drop to a Category 2 by the time it hits Japan, it has the potential to exacerbate the Fukushima situation by causing more flooding, or by further spreading radioactive particles (http://www.jma.go.jp/en/typh/1102.html).

The Odaka neighborhood seems frozen in time since it was abandoned after the tsunami nearly three months ago: Doors were left hanging open and bicycles were abandoned. A lone taxi sits in front of the train station. Mud-caked dogs roam empty streets, their barking and the cawing of crows the only sounds.

Many homes and businesses in the area escaped serious damage from the March 11 earthquake and tsunami, but their owners have not been allowed back because of concerns about radiation from the nearby nuclear plant crippled by the massive wave. Some have returned anyway, saying they need to get on with their lives.

“It’s eerie here,” said Masahiko Sakamoto, 59, who was loading a truck with two other workers Thursday in their company’s parking lot. “Everyone has gone. I think the number of people who have stayed is just about zero. Some people come back during the day. But it’s too scary at night.”Government officials have said it is important that the 70,000 to 80,000 people living in the zone stay away, but there are few roadblocks, and police are occupied with other duties and have, for the most part, not been forcing people out.

“I’d rather die from radiation than live in a shelter,” said 55-year-old Mitsuo Sato, who has food and electricity at his home in the evacuation zone but was riding his bike to get water from a well. “I don’t think the police know I’m here.”

A Japanese policeman wearing a protective radiation suit stands guard as his colleagues load a dead body into a van in the Odaka area of Minamisoma, inside the deserted evacuation zone established for the 20 kilometer radius around the Fukushima Dai-ichi nuclear reactors. (AP Photo/David Guttenfelder) #

A covered car sits in a garage where it was left behind in Odaka area of Minamisoma, inside the deserted evacuation zone established for the 20 kilometer radius around the Fukushima Dai-ichi nuclear reactors. (AP Photo/David Guttenfelder) #

A police roadblock is set up on an entry road to the Odaka area of Minamisoma, inside the deserted evacuation zone established for the 20 kilometer radius around the Fukushima Dai-ichi nuclear reactors. (AP Photo/David Guttenfelder) #

In this Thursday April 7, 2011 photo, abandoned dogs roam an empty street in the Odaka area of Minamisoma, inside the deserted evacuation zone established for the 20 kilometer radius around the Fukushima Dai-ichi nuclear reactors. (AP Photo/David Guttenfelder) #

Smoke rises in the distance behind destroyed houses in Kesennuma City in Miyagi Prefecture in northeastern Japan March 12, 2011.(REUTERS/Kyodo)

Coastal towns would be inundated. Schools, buildings and bridges would collapse, and economic damage could hit $32 billion. These findings were published in a chilling new report by the Oregon Seismic Safety Policy Advisory Commission, a group of more than 150 volunteer experts. In 2011, the Legislature authorized the study of what would happen if a quake and tsunami such as the one that devastated Japan hit the Pacific Northwest. The Cascadia Subduction Zone, just off the regional coastline, produced a mega-quake in the year 1700. Seismic experts say another monster quake and tsunami are overdue. “This earthquake will hit us again,” Kent Yu, an engineer and chairman of the commission, told lawmakers. “It’s just a matter of how soon.” When it hits, the report says, there will be devastation and death from Northern California to British Columbia. Many Oregon communities will be left without water, power, heat and telephone service. Gasoline supplies will be disrupted. The 2011 Japan quake and tsunami were a wakeup call for the Pacific Northwest. Governments have been taking a closer look at whether the region is prepared for something similar and discovering it is not. Oregon legislators requested the study so they could better inform themselves about what needs to be done to prepare and recover from such a giant natural disaster. The report says that geologically, Oregon and Japan are mirror images. Despite the devastation in Japan, that country was more prepared than Oregon because it had spent billions on technology to reduce the damage, the report says. Jay Wilson, the commission’s vice chairman, visited Japan and said he was profoundly affected as he walked through villages ravaged by the tsunami. “It was just as if these communities were ghost towns, and for the most part there was nothing left,” said Wilson, who works for the Clackamas County emergency management department. Wilson told legislators that there was a similar event 313 years ago in the Pacific Northwest, and “we’re well within the window for it to happen again.”

A car sits on top of a small building in a destroyed neighborhood in Sendai, Japan, on Sunday, March 13, 2011 after it was washed into the area by the tsunami that hit northeastern Japan. (AP Photo/David Guttenfelder) #

Police officers wearing respirators guide people to evacuate away from the Fukushima Daiichi nuclear plant following an evacuation order for residents who live in within a 10 km (6.3 miles) radius from the plant after an explosion in Tomioka Town in Fukushima Prefecture March 12, 2011. Japanese authorities battling to contain rising pressure in nuclear reactors damaged by a massive earthquake were forced to release radioactive steam from one plant on March 12, 2011 after evacuating tens of thousands of residents from the area. Tokyo Electric Power Co also said fuel may have been damaged by falling water levels at the Daiichi facility, one of its two nuclear power plants in Fukushima, some 240 km (150 miles) north of Tokyo. (REUTERS/Asahi Shimbun) #

A resident is rescued from debris in Natori, Miyagi, northern Japan Saturday, March 12, 2011, after one of the country's strongest earthquakes ever recorded hit its eastern coast on Friday. (AP Photo/Asahi Shimbun, Noboru Tomura) #

People evacuate with small boats down a road flooded by the tsunami waves in the city of Ishinomaki in Miyagi prefecture on March 12, 2011 a day after massive quake and tsunami hit the region. (JIJI PRESS/AFP/Getty Images) #

A man looks at the scene of devastation as he stands in the rubble in Rikuzentakata, northern Japan after the magnitude 9.0 earthquake and tsunami struck the area, March 13, 2011. (REUTERS/Toru Hanai) #

A person walks past an overturned squid-fishing boat tossed onto land by a tsunami in Hachinohe City, Aomori Prefecture, in northern Japan, March 13, 2011. (REUTERS/Kyodo)

Japan Earthquake, 2 Years Later: Before and After

In a few days, Japan will mark the 2nd anniversary of the devastating Tohoku earthquake and resulting tsunami. The disaster killed nearly 19,000 across Japan, leveling entire coastal villages. Now, nearly all the rubble has been removed, or stacked neatly, but reconstruction on higher ground is lagging, as government red tape has slowed recovery efforts. Locals living in temporary housing are frustrated, and still haunted by the horrific event, some displaying signs of post-traumatic stress disorder. Collected below are a series of before-and-after interactive images. Click on each one to see the image fade from before (2011) to after (2013).

The tsunami-devastated Kesennuma in Miyagi prefecture, is pictured in this side-by-side comparison photo taken March 12, 2011 (left) and March 4, 2013 (right), ahead of the two-year anniversary of the March 11 earthquake and tsunami that damaged so much of northeastern Japan.(Reuters/Kyodo)

This before-after pair of images shows a private plane, cars and debris outside Sendai Airport in Natori, Miyagi prefecture on March 13, 2011, and the same area two years later, on February 21, 2013. [click image to view transition](Mike Clarke, Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

A catamaran sightseeing boat washed by the tsunami onto a two-story tourist home in Otsuchi, Iwate prefecture on April 16, 2011, and (click to fade) the same area on February 18, 2013. [click image to view transition](Toru Yamanaka, Yasuyoshi Chiba, Toshifumi Kitamura/AFP/Getty Images) #

Residents crossing a bridge covered with debris in a tsunami-hit area of the city of Ishinomaki in Miyagi prefecture on March 15, 2011, and (click to fade) the same area nearly two years later on February 22, 2013. [click image to view transition](Kim Jae-Hwan, Toru Yamanaka/AFP/Getty Images) #

Residents look at a tsunami-damaged area of Minamisoma, Fukushima Prefecture, on March 12, 2011, and (click to fade) the same area on February 17, 2013. [click image to view transition] (Toru Yamanaka, Kazuhiro Nogi, Toshifumi Kitamura/AFP/Getty Images) #

Tsunami debris covers a large area of Natori, near Sendai in Miyagi prefecture on March 13, 2011, and (click to fade) the same field on February 21, 2013. [click image to view transition] (Mike Clarke, Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

A tsunami-hit area of Rikuzentakata, Iwate prefecture on March 29, 2011, and (click to fade) the same area on February 19, 2013. [click image to view transition] (Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

Residents walk past damaged cars on a street in a tsunami-damaged area of Tagajo, Miyagi prefecture on March 13, 2011, and (click to fade) the same street on February 21, 2013. [click image to view transition](Kim Jae-Hwan, Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

A tsunami-hit street in Ofunato, Iwate prefecture on March 14, 2011, and (click to fade) the same scene as it appeared on February 19, 2013.[click image to view transition] (Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

A rescue worker walks through rubble in the tsunami hit area of Minamisanriku, Miyagi prefecture on March 18, 2011, and (click to fade) the same area on February 20, 2013. [click image to view transition] (Mike Clarke, Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

A cherry blossom tree stands among tsunami debris in the city of Kamaishi, Iwate prefecture on April 20, 2011, and (click to fade) the same scene on February 18, 2013. [click image to view transition] (Toru Yamanaka, Yasuyoshi Chiba, Toshifumi Kitamura/AFP/Getty Images) #

A catamaran sightseeing boat washed by the tsunami onto a two-story home in Otsuchi, Iwate prefecture on April 16, 2011, and (click to fade) the same structure on February 18, 2013. [click image to view transition](Toru Yamanaka, Yasuyoshi Chiba, Toshifumi

On March 12, 2011, people evacuate down a road flooded by the tsunami in the city of Ishinomaki in Miyagi prefecture, click to fade the image and show the same road on February 22, 2013. [click image to view transition](Jiji Press, Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

A 10-meter tall pine tree stands in Rikuzentakata, Iwate prefecture on March 29, 2011, shortly after the tsunami. Click to see the same scene nearly two years later, on February 19, 2013. It was the only tree to have survived the tsunami among some 70,000 trees located by the seashore to protect from salt, sand and wind damage, but later died. The crane (2nd image) is working on a memorial to the tree. [click image to view transition] (Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

Tsunami-hit Ofunato, in Iwate prefecture on March 14, 2011, and (click to fade) the same scene as it appeared on February 18, 2013. [click image to view transition] (Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images) #

An image of the tsunami breaching an embankment and flowing into the city of Miyako, Iwate prefecture, taken by a Miyako City official on March 11, 2011, and (click to fade) the same scene on February 18, 2013, nearly two years later. [click image to view transition](Jiji Press, Toru Yamanaka, Toshifumi Kitamura/AFP/Getty Images)

IN THE ZONE: Diablo Canyon Nuclear Plant in California sits within the most active earthquake zone in the United States. (Photo: emdot/Flickr)

Nuclear power is under the microscope as much of the world watches the aftermath of the Japanese earthquake and the resulting tsunamis.

Let’s take a look at which nuclear power plants sit in the seismically active areas of the United States.

Generally, this concern is focused on the West Coast of the United States, because that's where most of our large earthquakes have occurred. There are no nuclear power plants in Hawaii or Alaska, but there are four nuclear reactor sites along the West Coast — one nuclear reactor site in Washington, two in California and one in Arizona.Here's a link to an interesting site, nukepills.com, where you can see the location of all nuclear power plants as well as the theoretical fallout zones.

Below, you can see the locations of the power plants, minus the fallout zones:

Now, these are just the power plants. There is a whole other issue with non-power nuclear reactors. These aren’t power plants, but research facilities such as universities where smaller-scale reactors are located. In all, there are eight of these sites along the West Coast. One is in Arizona, four are in California, two are in Oregon and one is in Washington. In all, the United States has 36 of these smaller sites, which can be seen below:

As you can see, most of the nuclear power plants and research facilities lie in the middle of the country. A good number that lie the West Coast are in the most seismically active parts of the nation, as this map from the United States Geological Survey shows:

Over the course of history, the concerns surrounding the nuclear industry have been focused on accidents that occurred despite safety regulations. This is what caused Chernobyl, and what has been blamed for the cause of Three Mile Island. While earthquakes and tsunamis can't be controlled, we can control what we know. And these maps allow us to know where the risks lie when it comes to nuclear industry and earthquakes.

Scientists claim they have answered one of the biggest questions in geology; why do tectonic plates beneath the Earth's surface sometimes move abruptly?

In a new study, US geologists believe the answer comes down to a combination of the thick crusts and weakened mineral grains.

Those effects acting together, they say, could explain a range of relatively 'speedy' moves among tectonic plates around the world, from Hawaii to East Timor.

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Traditionally, scientists believed that all tectonic plates are pulled by subducting slabs - which result from the colder, top boundary layer of the Earth's rocky surface becoming heavy and sinking slowly into the deeper mantle. Pictured is a diagram of a coastal area where an ocean plate is subducting beneath a continental plate

'Our planet is probably most distinctly marked by the fact that it has plate tectonics,' said Yale University geophysicist David Bercovici, lead author of the research.

'Our work here looks at the evolution of plate tectonics. How and why do plates change directions over time?'

Traditionally, scientists believed that all tectonic plates are pulled by subducting slabs - which result from the colder, top boundary layer of the Earth's rocky surface becoming heavy and sinking slowly into the deeper mantle.

Yet that process does not account for sudden plate shifts – which in geological terms is still a million years or longer.

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Thick crust from continents or oceanic plateaux is swept into the subduction zone prompting the slab to break off. The result is tectonic plates that abruptly shift horizontally, or continents suddenly bobbing up

Such abrupt movement requires that slabs detach from their plates, but doing this quickly is difficult since the slabs should be too cold and stiff to detach.

According to the Yale study, there are additional factors at work.

Thick crust from continents or oceanic plateaux is swept into the subduction zone, plugging it up and prompting the slab to break off.

The detachment process is then accelerated when mineral grains in the necking slab start to shrink, causing the slab to weaken rapidly.

The result is tectonic plates that abruptly shift horizontally, or continents suddenly bobbing up.

'Understanding this helps us understand how the tectonic plates change through the Earth's history,' Professor Bercovici said.

'It adds to our knowledge of the evolution of our planet, including its climate and biosphere.'

HOW EARTH GOT ITS CRUST: TINY GRAINS LED TO PLATE FORMATION

They are responsible for the formation of continents, and are still active - as earthquakes and volcanic eruptions show. However, researchers have never been able to work out why the Earth developed tectonic plates, but other planets did not.

But in April, they Yale said it had solved the mystery - and say the key is tiny minerals within rocks.

The research suggests how and when Earth came to develop one of its most distinct features — rigid tectonic plates — and why Venus, Earth’s twin-like neighbor, never has.

'We think it all comes down to the behavior of tiny grains of minerals within rocks,' said Yale geophysicist David Bercovici, lead author of research published online April 6 in the journal Nature.

The researchers argue that in Earth’s early days, mantle convection caused weak zones in the lithosphere - the outermost shell of the planet.

These zones persisted, developed into plate boundaries, and ultimately connected to form a global network of tectonic plates. The weak zones, they argue, resulted from the tendency of mineral grains in rocks to shrink as the rock deforms.

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What if the great 1906 San Francisco earthquake struck today?

Photographer Shawn Clover finds the exact spot each photo was taken and waits for the right light conditions

He studied archives of old photos taken at the time of the disaster

Around 25,000 buildings were destroyed by fire that raged for four days after the quake

These dramatic photographs show the streets of modern-day San Francisco torn apart by the after-effects of a violent earthquake.

Buildings are reduced to rubble, huge craters have opened in the debris-strewn roads and uncontrollable fires have ripped through homes.

Fortunately, these pictures are a clever amalgamation of images of the city today and after the devastating quake of 1906.

Trip back in time: A women opens the door to her Mercedes on Sacramento Street while horses killed by falling rubble lie in the street

Wonders of the modern world: A crowd from 1906 stare out over the burning city - and a 21st century bus

Foundations: Shoppers blithely cross the street while workers begin the monumental task of rebuilding a destroyed San Francisco

Breathtaking: Mr Clover returned almost 20 times to get the exact position and light right for this picture of the fallen Valencia St. Hotel

They were created by photographer Shawn Clover, a San Francisco resident who wanted to reimagine the traditional 'then-and-now' concept.

Mr Clover first selects a catalogue of historical photos and then takes new ones from the same spot, which he softly blends with the old. Once he has usable images, he has to recreate the exact conditions in which the original was taken - from where the photographer was positioned to where the sun is in the sky.

I found that many of the original photos I planned to use were in fact unusable because the photographer was situated in a place where a building stands today,' he writes on his blog. 'Others now have trees blocking the view.

'My goal is to stand in the exact spot where the original photographer stood,' he adds. 'Doing this needs to take into account equivalent focal length, how the lens was shifted, light conditions, etc.

Ghostly echoes: Mechanics Monument at Bush Street and Battery Street is surrounded by the shells of wrecked buildings from the past

Trash to tourism: Passing cable cars offer a view of the destruction of California Street. Cable cars at the time were crushed by rubble

Evocative: Fire fills the streets around Alamo Square - but does not quite reach the sunlit future - in one of Shawn Clover's mesmerising pictures

Broken windows: Cars park in front of the brand new US Courthouse, which survived the quake almost intact

'I take plenty of shots, each nudged around a bit at each location. Just moving one foot to the left changes everything.

He added: 'I kept running into delays. In the case of the Valencia St. Hotel, I had to return to the scene on Valencia between 18th and 19th four times before I managed to get it right. There’s quite a bit of conflicting information of exactly where this building once stood.

'And just when I was about to wrap things up, my dad announced that he had unearthed a local magazine published in late 1906 loaded with earthquake-aftermath photos that I had never seen in any library or online collection.'

Photography was a common hobby by 1906 and thousands of photos have survived to this day. One photographer even flew his £46 camera on a kite to get aerial shots of the aftermath. Some colour photographs have even been found.

Strange visions: Modern day business people and a child from 1906 face the camera while fire consumes a building on the corner of Franklin St and Hayes St

Fade out: Cheerful tourists pass by the Fairmont Hotel, which still stands, but is destroyed inside from the fires

Always prepared: Men pose in a tent city to house displaced residents while an armoured car turns left a corner

In ruins: Buildings fell, sinkholes in the streets opened up, railroad tracks bent, and collapsing bricks crushed cable cars during the disaster

The 42 seconds of intense shaking made building collapse, sinkholes in the streets open up, railroad tracks bend, and collapsing bricks crush cable cars.

Four-day-long fires were responsible for 90 per cent of the destruction, with more than 30, caused by ruptured gas mains, destroying around 25,000 buildings on 490 city blocks.

Many were started when firefighters untrained in the use of dynamite attempted to demolish buildings to create firebreaks, and the dynamited buildings themselves caught fire.

Mayor Eugene Schmitz put out an authorization for the federal troops and police to shoot and kill looters. Thousands of tents and temporary relief houses went up to house 20,000 displaced people.

Mr Clover has spent more than two years recreating the chaos in 1906 + 2010: The Earthquake Blend.

Ode to San Fran: A tourist takes a photo of a cable car heading towards the California St incline - if only he could see the aimless people of the past

Masterpiece: Two girls stand before the partially destroyed Sharon Building in Golden Gate Park while students work on their art projects inside

Underground artwork: A woman walks dangerously close to a pit of rubble on 5th St by the US Mint

At 5:12 AM on April 18, 1906, San Franciscans woke up to a quick jolt. For the next 25 seconds, all was silent. And then it hit hard–42 seconds of intense shaking. Buildings fell, sinkholes in the streets opened up, railroad tracks bent, and collapsing bricks crushed cable cars sheltered for the night in the cable car barn. But the real damage had not even begun. It was the out-of-control fires that did 90% of the destruction to San Francisco. Over 30 fires, caused by ruptured gas mains, destroyed approximately 25,000 buildings on 490 city blocks. Worst of all, many were started when the military, untrained in the use of dynamite, attempted to demolish buildings to create firebreaks, which resulted in the destruction of more than 50% of the buildings that would have otherwise survived. The dynamited buildings themselves often caught fire. In all, the fires burned for four days and nights.

Mayor Eugene Schmitz put out an authorization for the federal troops and police to shoot and kill looters. Thousands of tents and temporary relief houses went up to house 20,000 displaced people. The city was in disarray. But photography was a common hobby by 1906 and thousands of photos have survived to this day. One photographer even flew his 46 pound camera on a kite to get aerial shots of the aftermath. Some color photographs have even been found.

It’s been two years since I posted the first installment of this series, 1906 + 2010: The Earthquake Blend (Part I). I kept running into delays. In the case of the Valencia St. Hotel, I had to return to the scene on Valencia between 18th and 19th four times before I managed to get it right. There’s quite a bit of conflicting information of exactly where this building once stood. And just when I was about to wrap things up, my dad announced that he had unearthed a local magazine published in late 1906 loaded with earthquake-aftermath photos that I had never seen in any library or online collection. On the plus side, I’ve got plenty more material for a part three now.

To put these photos together, I first create a catalog of historical photos that look like they have potential to be blended. Unfortunately most of these photos end up on the digital cutting room floor because there’s simply no way to get the same photo today because either a building or a tree is in the way. Once I get a good location, I get everything lined up just right. My goal is to stand in the exact spot where the original photographer stood. Doing this needs to take into account equivalent focal length, how the lens was shifted, light conditions, etc. I take plenty of shots, each nudged around a bit at each location. Just moving one foot to the left changes everything.

People walk beneath Old Saint Mary’s Cathedral, which survived the quake but was gutted by the fire

People mill around Lotta’s Fountain, which served as a meeting place after the quake

The Conservatory of Flowers stands undamaged as now-homeless citizens camp in a tent shelter

A bicyclist rides towards the fallen Valencia St. Hotel and a huge sinkhole that has opened up in the street

People stroll by the original adobe Mission Dolores which survived, while the brick church next door was destroyed

Horse carriages and cars park in front of Lafayette Park while a destroyed city looms in the background

People cross Market Street in front of the destroyed Hearst Building

People walk through rubble on Geary St

People walk up California St amid charred scraps of lumber

Cars park in front of the brand new US Courthouse which fared well in the quake

HISTORICAL NOTES

The Cable Car Barn & Powerhouse was completely dismantled and rebuilt from 1982-1984. The Washington Street facade depicted is different in design than that of 1906, but the garage opening and tracks are in the exact same place to the best of my knowledge.

Lotta’s Fountain has moved around over the years. It was raised eight feet in 1916, smashed by a drunk driver in 1954, moved 10 feet in 1975, and completely stripped down and rebuilt in 1998. I lined it up the best I could, but it was obvious when I was overlaying the photos that things weren’t perfect. The Palace Hotel in the background was demolished after the quake and rebuilt to the “new” Palace Hotel that I’ve blended with the old one.

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